Method to impart electro- and biofunctionality to neural scaffolds using graphene-polyelectrolyte multilayers

Date

2012

Authors

Zhou, Kun
Thouas, George A
Bernard, Claude C
Nisbet, David
Finkelstein, David
Li, Dan
Forsythe, John S.

Journal Title

Journal ISSN

Volume Title

Publisher

American Chemical Society

Abstract

Electroactive scaffolds that are passively conductive and able to transmit applied electrical stimuli are of increasing importance for neural tissue engineering. Here, we report a process of rendering both 2D and 3D polymer scaffolds electrically conducting, while also enhancing neuron attachment. Graphene-heparin/poly-l-lysine polyelectrolytes were assembled via layer-by-layer (LbL) deposition onto 2D surfaces and 3D electrospun nanofibers. The employed LbL coating technique in this work enables the electro- and biofunctionalization of complex 3D scaffold structures. LbL assembly was characterized by a steady mass increase during the in situ deposition process in 2D, with regular step changes in hydrophobicity. Uniform coverage of the graphene/polyelectrolyte coatings was also achieved on nanofibers, with hydrodynamic flow and post-thermal annealing playing an important role in controlling sheet resistance of 2D surfaces and nanofibers. Cell culture experiments showed that both 2D and 3D graphene-PEMs supported neuron cell adhesion and neurite outgrowth, with no appreciable cell death. This electroactive scaffold modification may therefore assist in neuronal regeneration, for creating functional and biocompatible polymer scaffolds for electrical entrainment or biosensing applications.

Description

Keywords

Keywords: 3D scaffolds; Biocompatible polymer; Biofunctionality; Biofunctionalization; Biosensing applications; Electrical stimuli; Electroactive; Electrospun nanofibers; Hydrodynamic flows; In-situ deposition; Layer by layer deposition; Layer-by-layers; Mass incre graphene; layer-by-layer; nanofibers; neural tissue engineering; polyelectrolyte multilayers; scaffolds

Citation

Source

ACS Applied Materials and Interfaces

Type

Journal article

Book Title

Entity type

Access Statement

License Rights

Restricted until

2037-12-31